Validation of Flow Field and Heat Transfer in a Two-Pass Internal Cooling Channel Using Different Turbulence Models

Abstract: In this work the flow regime within a generic turbine cooling system is investigated numerically. The main objective is to validate the performance of various turbulence models with different complexity by comparing the numerical results with experimental data. To maximize surface heat transfer rates, present-day cooling systems of high pressure turbines have highly complex shapes generating high turbulence levels and flow separations. These flow structures lead to higher requirements of CFD-techniques for suf… Show more

“…Therefore, the mesh with 9.27 million node and 20 inflation layers is adopted in this study. This numerical study is conducted by the commercial software ANSYS CFX 14.0 with the Shear Stress Turbulence (SST) turbulence model, which has been proved to have satisfying accuracy in the simulation of ribbed channel [15][16][17]. In this numerical study, boundary conditions are selected to mimic the experimental work of Mochizuki et al [8].…”

Improving heat transfer performance in two-pass ribbed channel by the optimized secondary flow via bend shape modification

“…Therefore, the mesh with 9.27 million node and 20 inflation layers is adopted in this study. This numerical study is conducted by the commercial software ANSYS CFX 14.0 with the Shear Stress Turbulence (SST) turbulence model, which has been proved to have satisfying accuracy in the simulation of ribbed channel [15][16][17]. In this numerical study, boundary conditions are selected to mimic the experimental work of Mochizuki et al [8].…”

Improving heat transfer performance in two-pass ribbed channel by the optimized secondary flow via bend shape modification